SSC JE Electrical 2018 with solution SET-1

An AC or DC generator requires direct current to energize its magnetic field. The DC field current is obtained from a separate source called an exciter. Either rotating or static-type exciters are used for AC power generation systems. There are two types of rotating exciters: brush and brushless. The primary difference between brush and brushless exciters is the method used to transfer DC exciting current to the generator fields. Static excitation for the generator fields is provided in several forms including field-flash voltage from storage batteries and voltage from a system of solid-state components. DC generators are either separately excited or self-excited.
EXCITATION SYSTEMS in current use include direct-connected or gear-connected shaft-driven DC generators, belt-driven or separate prime mover or motor-driven DC generators, and DC supplied through static rectifiers.
Static Excitation System
As the name indicates, all the components in this type of excitation system are static. A set of rectifiers is fed from a transformer that steps down the main generator or auxiliary bus voltage. The rectifiers supply the main generator excitation current directly through slip rings and they may be controlled or uncontrolled.
 
An external source of DC is necessary for the initial excitation of the field windings. On engine-driven generators, the initial excitation may be obtained from the storage batteries used to start the engine or from control voltage at the switchgear.
The main advantage of the static exciter is improved response as the field current is controlled directly by the thyristor rectifier but, of course, if the generator terminal voltage is depressed too low then excitation power will be lost. It is again possible to provide the power supply from both voltage and current transformers at the generator terminals but it is doubtful whether the improved response of the static exciter over a permanent magnet brushless scheme can be justified for many small embedded generators.
 

Cavity Fixings are used to create reliable fixings into hollow walls and ceiling.
 
 Rawlplug’Uno’ Plugs have a universal function. Their patented zigzag expansion pattern allows them to form a secure fixing into hollow walls, or any other type of wall, ceiling or floor. They are suitable for all light to medium weight applications and are color-coded in Yellow, Red and Brown for screw gauges ranging from 3.0 mm to 6.0 mm, with plug lengths of 24, 28, 30 and 32 mm. Corresponding drill-holes are 5, 6, 7 and 8 mm diameter.
 

 
Current through the 10Ω resistance
I1 = V/R = 20/10 = 2A
I1 = 2A
Now current through the 20Ω resistance
I2 = V − (-10)/R = (20 + 10)/20 = 1.5 A
I2 = 1.5 A
 

DESIGN CONSIDERATIONS IN A DISTRIBUTION SYSTEM
Good voltage regulation is the most important factor in a distribution system for delivering good service to the consumer. For this purpose, careful consideration is required for the design of feeders and distributor networks.
Feeders:- Feeder are the conductors that connect substations to consumer ports and have the large current-carrying capacity. The current loading of a feeder is uniform along the whole of its length since no lappings are taken from it. The design of a feeder is based mainly on the current that is to be carried.
Distributors:- Distributors are the conductors, which run along a street or an area to supply power to consumers. These can be easily recognized by the number of tappings, which are taken from them for the supply to various consumer terminals. The current loading of a distributor is not uniform and it varies along the length while its design is largely influenced by the voltage drop along with it.
Service Main and Sub Main:- Thc service mains are the conductors forming connecting links between distributors and metering points of the consumer’s terminal The term sub main refers to the several connections given to consumers from one service main. The area of the cross-section of a sub-main conductor is greater than that of the service mains.

A Bipolar Junction Transistor (BJT) is a three-layer, two junction semiconductor device consisting of either two N-type and one P-type layer of material (NPN transistor) or two P-type and one N-type layer of material (PNP transistor). A transistor can be visualized as two back-to-back connected diodes; by placing two PN junctions together, we can create a bipolar transistor with the three terminals – emitter, base, and collector. The term bipolar is to justify the fact that holes and electrons participate in the injection process into the oppositely polarised material. If only one carrier is employed (electron or hole), it is considered a unipolar device. For proper working of the transistor, the two junctions of the transistor should be properly biased, the base-emitter (J1) junction should be forward biased and the base-collector (J2) junction should be reverse biased. In a PNP transistor, the majority charge carriers are holes and germanium is favored for these devices. In an NPN transistor, the majority charge carriers are electrons and silicon is best for NPN transistors. The thin and lightly doped middle layer is known as the base (B) and the two outer regions are known as the emitter (E) and the collector (C).
Under the proper operating conditions, the emitter region emits or injects majority charge carriers into the base region and because the base is very thin, most of these electrons will ultimately reach the collector. The emitter is highly doped to reduce resistance and emit more majority charge carriers. The collector is lightly doped to reduce the junction capacitance of the collector-base junction. The schematics and the circuit symbols for bipolar transistors are shown in Fig. The arrows on the schematic symbols indicate the direction of emitter-current flow. The collector is usually at a higher voltage than the emitter and for proper operation, the base-emitter junction is forward biased while the collector-base junction is reverse biased.
 

SPLIT-PHASE MOTORS
Split-phase motors also referred to as induction-star induction-run (ISIR) motors, have a relatively low starting torque compared with the other single-phase motors but more torque than the shaded-pole motor. They range in size from 1/20 horsepower to abort 1/3 horsepower. Split-phase motors get their name from the fact that a single power supply is split between two individual windings — the run and the start — to produce the necessary torque to start the Motor.
A split phase induction motor is provided with the main winding and auxiliary or start winding placed in space quadrature and are connected in parallel to a single-phase supply. The main winding has a low resistance and high reactance whereas the auxiliary winding has a high resistance and low reactance. The auxiliary winding is effective during the starting of the motor and is disconnected from the supply when the motor attains 75 percent of its synchronous speed. A centrifugal switch, S is used to disconnect the auxiliary winding from the source as shown in Fig. Under the normal running condition, only the main winding is effective.
The run winding is energized whenever the motor is energized. This winding has a lower resistance than the start winding, which is only in the circuit long enough to help the motor start. For the motor to start, both the start and run windings must be energized. When both windings are energized, the current flows through each of the windings at a different rate, creating a phase shift.
The phase shift is measured in electrical degrees and is often referred to as the phase angle. The larger the phase angle, the more starting torque a motor has. For a point of future reference, a split-phase motor, as just described, has a phase angle of about 30° degrees. If the run and start windings were constructed and configured exactly the same, with the same size wire and the same number of turns, the phase angle would be zero, the magnetic field would have no imbalance, and the motor would not start.
Once the split-phase motor has started, the start winding must be removed from the electric circuit. The start winding is designed to be energized for only a short time and can become damaged if it is not de-energized. One commonly used device to remove the start winding from the circuit is the centrifugal switch (Fig.), which opens and closes its contacts depending on the speed of the motor. The electrical contacts on the switch are connected in series with the start winding and are normally closed.
When the voltage is initially applied to the motor, both the start and run windings are energized and the motor begins to turn. Once the motor has reached a speed equal to about 70 percent of its rated speed, the contacts oi the centrifugal switch open, de-energizing the start winding. The run winding, or main winding, is now the only winding energized, and the motor continues to run in this fashion since the turning rotor now creates the imbalance needed to keep the motor running. When the motor is de-energized, it begins to slow down and the centrifugal switch closes in preparation for the next startup. Other components can be added to the split-phase motor to increase its torque, as well as its range of applications such as the capacitor, potential relay etc.